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Chemical Building Blocks of Life
Chapter 3
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Biological Molecules
Biological molecules consist primarily of
-carbon bonded to carbon, or
-carbon bonded to other molecules.
Carbon can form up to 4 covalent bonds.
Carbon may be bonded to functional groups with specific properties.
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Biological Molecules
Isomers are molecules with the same
chemical formula.
-structural isomers
-stereoisomers
Chiral molecules are mirror-images of each
other.
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Biological Molecules
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Biological Molecules
Biological molecules are typically large
molecules constructed from smaller
subunits.
Monomer: single subunit
(mono = 1; -mer = unit)
Polymer: many units
(poly = many)
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Biological Molecules
dehydration synthesis: formation of large
molecules by the removal of water
-monomers are joined to form polymers
hydrolysis: breakdown of large molecules
by the addition of water
-polymers are broken down to monomers
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Biological Molecules
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Carbohydrates
Molecules with a 1:2:1 ratio of carbon,
hydrogen, oxygen
-empirical formula: (CH2O)n
-examples: sugars, starch, glucose
C – H covalent bonds hold much energy
Carbohydrates are good energy storage
molecules.
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Carbohydrates
Glucose
-a monosaccharide – single sugar
-contains 6 carbons
-very important in energy storage
-fructose is a structural isomer of glucose
-galactose is a stereoisomer of glucose
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Carbohydrates
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Carbohydrates
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Carbohydrates
Disaccharides
-2 monosaccharides linked together by
dehydration synthesis
-used for sugar transport or energy
storage
-examples: sucrose, lactose, maltose
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Carbohydrates
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Carbohydrates
Polysaccharides
-long chains of sugars
-used for energy storage
-plants use starch; animals use glycogen
-used for structural support
-plants use cellulose; animals use chitin
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Carbohydrates
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Carbohydrates
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Carbohydrates
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Nucleic Acids
Two types: DNA and RNA
Functions: specialized for the storage,
transmission, and use of genetic
information
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Nucleic Acids
Nucleic acids are polymers of nucleotides.
-nucleotides:
sugar + phosphate + nitrogenous base
-sugar is deoxyribose in DNA
or ribose in RNA
-Nitrogenous bases include
-purines: adenine and guanine
-pyrimidines: thymine, cytosine, uracil
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Nucleic Acids
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Nucleic Acids
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Nucleic Acids
DNA
-nucleotides connected by phosphodiester
bonds
- double helix: 2 polynucleotide strands
connected by hydrogen bonds
-polynucleotide strands are complementary
-genetic information is carried in the
sequence of nucleotides
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Nucleic Acids
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Nucleic Acids
RNA
-contains ribose instead of deoxyribose
-contains uracil instead of thymine
-single polynucleotide strand
-functions:
-read the genetic information in DNA
-direct the synthesis of proteins
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Nucleic Acids
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Nucleic Acids
Other nucleotides
-ATP: adenosine triphosphate
-primary energy currency of the cell
-NAD+ and FAD: electron carriers for many
cellular reactions
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Proteins
Protein functions include:
1. enzyme catalysts
2. defense
3. transport
4. support
5. motion
6. regulation
7. storage
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Proteins
Proteins are polymers of amino acids.
Amino acids
-20 different amino acids
-joined by dehydration synthesis
-peptide bonds form between adjacent
amino acids
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Proteins
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Proteins
Amino acid structure
-central carbon atom surrounded by
-amino group
-carboxyl group
-single hydrogen
-variable R group
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Proteins
The structure of the R group dictates the chemical properties of the amino acid.
Amino acids can be classified as:
1. nonpolar
2. polar
3. charged
4. aromatic
5. special function
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Proteins
The shape of a protein determines its function.
-primary structure – sequence of amino acids
-secondary structure – interaction of groups in
the peptide backbone
-a helix
-b sheet
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Proteins
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Proteins
Protein structure (continued)
-tertiary structure – folded shape of the
polypeptide chain
-quaternary structure – interactions between
multiple polypeptide subunits
Protein folding is aided by chaperone
proteins.
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Proteins
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Proteins
Motifs are common elements of secondary
structure seen in many polypeptides.
Domains are functional regions of a
polypeptide.
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Proteins
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Proteins
Denaturation is a change in the shape of a
protein, usually causing loss of function.
-may involve complete unfolding
-caused by changes in the protein’s
environment
-pH
-temperature
-salt concentration
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Proteins
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Lipids
Lipids are a group of molecules that are
insoluble in water.
A high proportion of nonpolar C – H bonds
causes the molecule to be hydrophobic.
Two main categories:
-fats (triglycerides)
-phospholipids
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Lipids
Triglycerides (fats)
-composed of 1 glycerol + 3 fatty acids
Fatty acids are long hydrocarbon chains which may be
-saturated
-unsaturated
-polyunsaturated
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Lipids
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Lipids
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Lipids
Triglycerides
-an excellent molecule for energy storage
-store twice as much energy as
carbohydrates
-animal fats are usually saturated fats and
are solid at room temperature
-plant fats (oils) are usually unsaturated and
are liquid at room temperature
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Lipids
Phospholipids -composed of:
-1 glycerol
-2 fatty acids
-a phosphate group
Phospholipids contain polar “heads” and
nonpolar “tails”.
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Lipids
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Lipids
Phospholipids spontaneously form micelles or lipid bilayers.
These structures cluster the hydrophobic regions of the phospholipid toward the inside and leave the hydrophilic regions exposed to the water environment.
Lipid bilayers are the basis of biological membranes.
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Lipids
Chemical Evolution
H2O
CH4 (methane)
NH3 (ammonia)
H2 Miller & Urey 1953
Amino Acids Urea
Fatty Acids Simple Fatty Acids
15% of carbon
converted to organic
compounds such as:
Oparin-Haldane Hypothesis
early atmosphere contains
No O2